JP2000136772A - Pump device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To exhibit excellent durability and pump performance by integrally connecting an inverter to a pump through a transmission device, and constituting so as to circulate a cooling fluid to the pump, the transmission device, an electric motor and the inverter. SOLUTION: When turning on a switch of a control board 5, an electric motor 4 is rotated while changing a rotating speed through an inverter 7, the motive power is transmitted to a Roots pump 3 through a transmission device 2, and air sucked in from a suction port is boosted by the Roots pump 3 to be delivered from an exhaust port. When operating this pump, cooling water supplied from a supply device through an inlet pipe 6a is circulated to the electric motor 4, the inverter 7, the transmission device 2 and the Roots pump 3 to cool respective parts while being carried out of an outlet pipe 6b. Thus, the degradation of a rubber member and a lubrication shortage can be prevented, and compression efficiency can be maintained at a high level.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pump device in which an electric motor drives a pump such as a roots pump, and the pump performs a pumping operation.

[0002]

2. Description of the Related Art In a commercially available pump device, an electric motor is connected to a pump such as a roots pump via a transmission device. For example, in a commercially available pump device using a roots pump having two rotors as one set, a drive shaft of an electric motor is connected to one end of one rotation shaft of the roots pump and a timing gear is connected to the other end. Are concatenated,
This timing gear meshes with another timing gear connected to another rotating shaft extending parallel to the rotating shaft. In the single-stage roots pump, a single pump chamber is formed, and each rotating shaft holds a rotor rotatably in the pump chamber. Further, in the multi-stage roots pump, a plurality of pump chambers which are sequentially communicated with each other are formed, and a rotor is rotatably held on each rotating shaft in each pump chamber.

When the switch of the electric motor of the pump device is turned on, the roots pump is driven.
For this reason, since the rotors mesh with each other and rotate in one or a plurality of pump chambers, for example, it is possible to perform a pump action of sucking air or the like from the suction port and discharging the air or the like from the exhaust port. This makes it possible to evacuate a certain room to form a decompression room.

[0004]

However, in the above-mentioned commercially available pump device, the drive shaft of the electric motor can be rotated only at a constant rotational speed. For this reason, in this pump device, wasteful power is consumed even under a request to maintain the degree of vacuum in the decompression chamber, which is uneconomical, and the pump performance cannot be changed. It is inconvenient because it cannot cope with the demand for evacuation.

In this regard, it is conceivable to connect an inverter to the electric motor. This makes it possible to change the rotation speed of the drive shaft of the electric motor while changing the power to be consumed, and to select one of them, thereby enabling economical and convenient operation. However, if a general inverter separate from the electric motor is used, a space for arranging the inverter itself in the pump device is required, and the installation place (footprint) of the pump device is enlarged, and the installation is difficult. Will also occur. In particular, a general inverter has its own fan and fin for cooling the heat generated by an internal transformer or the like, and is therefore large in size, and such a problem is large.

On the other hand, even if an inverter integrated with an electric motor is employed, if the electric motor and the inverter are merely air-cooled by a fan or the like, the electric motor generates frictional heat or the like, and the inverter generates heat by a transformer or the like. However, those heats are not sufficiently cooled unless the fan and the like are made relatively large, and they become hot. For these reasons, in these, deterioration of rubber members and the like and insufficient lubrication occur, so that excellent durability cannot be exhibited, and the heat is transferred to the pump, and the pump performance cannot be maintained because the fluid compression efficiency cannot be maintained. It may be inferior.

If the means for cooling the pump and the transmission and the means for cooling the electric motor and the inverter are provided independently of each other, the cost will increase. The present invention has been made in view of the above-described conventional situation, is capable of economical and convenient operation, can be easily installed due to a reduced footprint, and can exhibit excellent durability and pump performance. It is an object of the present invention to provide a pump device which can be manufactured at a relatively low cost.

[0008]

A pump device according to the present invention comprises:
A pump device having a pump and an electric motor connected to the pump via a transmission, wherein an inverter provided integrally with the electric motor is connected to the pump, the transmission, and the electric motor. The motor and the inverter are characterized in that the cooling fluid can be circulated in common.

In this pump device, since the inverter is connected to the electric motor, it is possible to change the number of revolutions of the drive shaft of the electric motor while changing the power to be consumed, and to select one of them. Convenient driving becomes possible. Further, in this pump device, since the electric motor and the inverter are provided integrally, the inverter can be arranged together with the electric motor, so that the footprint of the pump device does not increase so much and installation is easy.

Further, in this pump device, the pump, the transmission, the electric motor, and the inverter can be cooled by the circulating cooling fluid. For this reason, in this pump device,
Even when the pump generates frictional heat or heat when a fluid such as air is pressurized, a transmission device such as a timing gear generates frictional heat, the electric motor generates frictional heat or the like, and the inverter generates heat by a transformer or the like. , Their heat is well cooled and they do not get hot. Therefore, in these, it is possible to exhibit excellent durability because deterioration and insufficient lubrication of the rubber member and the like hardly occur, and it is also possible to maintain excellent fluid compression efficiency and exhibit excellent pump performance. .

In this pump device, since the cooling of the pump, the transmission, the electric motor and the inverter is performed by a common circulating cooling fluid, the cost can be reduced as compared with the case where the cooling is performed independently of each other. Has been realized.
Therefore, the pump device of the present invention can be operated economically and conveniently, can be easily installed due to a reduced footprint, can exhibit excellent durability and pump performance, and can be manufactured at a relatively low cost. It can be manufactured.

Preferably, the inverter is in contact with the electric motor. In this case, the heat of the inverter is conducted to the electric motor in which the cooling fluid is circulated and cooled, and the inverter circulates in common with the electric motor without providing a cooling fluid circulation circuit, a fan, a fin, or the like. The cooling fluid can cool the inverter, and the inverter itself can be downsized. For this reason, it is possible to further realize the ease of installation by reducing the cost and the footprint. The contact area between the inverter and the electric motor can be set according to the amount of heat generated by the inverter.

When the inverter is brought into contact with the electric motor, if a roots pump is used as the pump, it is preferable that the inverter be located on a plane formed by a plurality of rotation shafts of the roots pump. For example, if a plurality of rotating shafts of the roots pump are arranged vertically, it is preferable that the inverter be in contact with the upper part of the electric motor. It is preferable to contact the side of the electric motor. Thereby, the inverter is located in a useless space formed by the roots pump and the electric motor, and the space is saved. In particular, when arranging a plurality of rotation axes of the roots pump in the vertical direction,
Since the footprint can be reduced, the difficulty of installation can be reduced.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments 1 and 2 embodying the present invention will be described below with reference to the drawings. (Embodiment 1) In this pump device, as shown in FIG. 1, a roots pump 3 having a transmission 1 integrated on a base 1
, The electric motor 4, the control panel 5, and the flow meter 6 are fixed.

The roots pump 3 has five sets of two rotors (not shown), one set of which is shown in FIG. 4. As shown in FIG. 4, one rotary shaft 3a of the roots pump 3 extends horizontally below. The other rotating shaft 3b extends horizontally above the rotating shaft 3a. Five pump chambers (not shown) which are sequentially communicated with each other are formed in a housing forming an outer shell of the roots pump 3, and five rotors are fixed to the rotation shaft 3a so as to be rotatable in each pump chamber. Five rotors are rotatably fixed in each pump chamber. As shown in FIGS. 2 and 3, a water jacket 3c is formed in the housing of the roots pump 3 so as to form a later-described path. Further, the housing has a suction port (not shown) communicating with the first-stage pump chamber on the rear side,
An exhaust port (not shown) communicating with the fifth-stage pump chamber on the front side is formed.

The transmission 2 integrally provided in front of the roots pump 3 has one set of two timing gears (not shown) in the vertical direction.
The front end of the rotating shaft 3a is connected to a lower timing gear, and the front end of the rotating shaft 3b of the roots pump 3 is connected to an upper timing gear. A water jacket 2a is formed on a housing that forms an outer shell of the transmission device 2 and forms a forward path described later.

The electric motor 4 is located forward of the transmission 2, and a drive shaft (not shown) of the electric motor 4 is also connected to a lower timing gear via a coupling. As shown in FIG. 4, the upper surface of the housing forming the outer periphery of the electric motor 4 is a horizontal contact surface 4a, and is integrally fixed with the inverter 7 in contact with the contact surface 4a. ing. As shown in FIGS. 2 and 3, the housing of the electric motor 4 is also formed with a water jacket 4 b which forms a forward path described later.

The control panel 5 is located in front of the electric motor 4, and the control panel 5 is connected to the electric motor 4 and the flow meter 6 by lead wires. An inlet pipe 6a and an outlet pipe 6b are connected to a flow meter 6 located on the side of the control panel 5. Inlet pipe 6a
Is supplied with cooling water from a supply device (not shown). The flow meter 6 detects the flow rate of the cooling water in the inlet pipe 6a or the outlet pipe 6b and sends a signal to the control panel 5 through a lead wire. It is configured to send.

A pipe 8 is connected to the inlet pipe 6a, and this pipe 8 communicates with an inlet port of a water jacket 4b located in front of the electric motor 4. The water jacket 4b of the electric motor 4 makes a round around the housing of the electric motor 4 while winding back and forth, and communicates with an outlet port located at the rear. A pipe 9 is connected to an outlet port of the water jacket 4 b of the electric motor 4, and the pipe 9 is connected to an inlet port of the water jacket 2 a of the transmission 2. The water jacket 2a of the transmission 2 extends upward, then in the width direction, and then extends downward, and then communicates with the inlet port of the water jacket 3c of the roots pump 3. The water jacket 3c of the roots pump 3 is located rearward from its inlet port (near the first stage; it can be at the fourth or fifth stage).
After extending upward, extending upward, extending in the width direction, and then extending downward, extending forward, and thereafter, repeatedly extending upward, in the width direction, downward, and forward, and forwardly To the outlet port located at A pipe 10 is connected to an outlet port of the water jacket 3c of the roots pump 3, and the pipe 10 communicates with the outlet pipe 6b.

In the pump device configured as described above, when the switch of the control panel 5 is turned on, the drive shaft of the electric motor 4 can be rotated while changing the rotation speed via the inverter 7. At this time, since the inverter 7 is employed, there is no waste in power consumption. As a result, the roots pump 3 is driven via the transmission device 2 and the respective rotors mesh with each other and rotate in the plurality of pump chambers, so that a pump action of sucking air from the suction port and discharging the air from the exhaust port is performed. be able to. This makes it possible to evacuate a certain room to form a decompression room.
In particular, since the pump device employs the inverter 7, it is economical and can change the pump performance without wasting power even under the demand to maintain the degree of vacuum in the decompression chamber. It is convenient because it can cope with the demand to quickly evacuate a certain room.

During this time, in this pump device, the electric motor 4, the inverter 7, the transmission device 2, and the roots pump 3 are cooled by the cooling water supplied from the supply device.
Even when the roots pump 3 generates frictional heat or heat when the air fluid is pressurized, the transmission 2 generates frictional heat, the electric motor 4 generates frictional heat, etc., and the inverter 7 generates heat by a transformer or the like. , Their heat is well cooled and they do not get hot. Therefore, in these, it is possible to exhibit excellent durability because deterioration and insufficient lubrication of the rubber member and the like hardly occur, and it is also possible to maintain excellent air compression efficiency and exhibit excellent pump performance. .

In particular, in this pump device, the inverter 7
Is contacted above the electric motor 7, the heat of the inverter 7 is transmitted to the electric motor 4 in which the cooling water is circulated and cooled, and the inverter 7 itself is provided with a cooling water circulation circuit, a fan, fins, and the like. Even if the inverter 7 is not provided, the inverter 7 can be cooled by the cooling water commonly circulating in the electric motor 4 and the like, and the inverter 7 itself can be downsized. For this reason, it is possible to further realize the ease of installation by reducing the cost and the footprint.

Further, in this pump device, the electric motor 4, the inverter 7, the transmission 2, and the roots pump 3 are cooled by common circulating cooling water. The cost is also reduced. Further, in this pump device, the plurality of rotation shafts 3a, 3b of the roots pump 3 are arranged in the vertical direction,
Since the inverter 7 is in contact with the upper part of the electric motor 4, the inverter 7 is located in a useless space formed by the roots pump 3 and the electric motor 4, thereby saving space. For this reason, the footprint is reduced in this sense, and the difficulty in installation is reduced. (Embodiment 2) In this pump device, as shown in FIG. 5, a plurality of rotating shafts 3a and 3b of a roots pump 3 are arranged in a horizontal direction on a base 1, and an inverter 7 Abutting. Other configurations are the same as in the first embodiment.

Although this pump device does not reduce the difficulty of installation due to the reduction of the footprint, it can easily be installed in a place where the height is limited, and other functions and effects are achieved in the first embodiment. Can be played in the same way as Although the roots pump 3 is used in the first and second embodiments, other pumps may be used in the present invention.

[Brief description of the drawings]

FIG. 1 is a perspective view of a pump device according to a first embodiment.

FIG. 2 is a plan view of the pump device according to the first embodiment.

FIG. 3 is a side view of the pump device according to the first embodiment.

FIG. 4 relates to the pump device of the first embodiment, and is shown in FIGS. 2 and 3;
FIG. 4 is a sectional view taken along line IV-IV of FIG.

FIG. 5 is a cross-sectional view of a pump device according to a second embodiment, similar to FIG.

[Explanation of symbols]

 3. Pump (Roots pump) 2. Transmission device 4. Electric motor 7. Inverter

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification FI FI Theme Court II (Reference) F04C 29/04 F04C 29/04 H (72) Inventor Nobuaki Hoshino 2-1-1 Toyota-cho, Kariya City, Aichi Prefecture Stock F term in Toyota Industries Corporation (reference) 3H003 AA01 AB06 AC02 BE00 BE04 BE06 BE09 CD06 CF01 3H029 AA06 AA15 AA22 AB02 AB06 BB12 CC27 CC48 3H044 AA00 BB06 BB08 CC00 CC10 CC12 CC14 CC19 DD01 DD11 DD18 DD19 DD24

Claims (2)

[Claims] 1. A pump device having a pump and an electric motor connected to the pump via a transmission, wherein an inverter provided integrally with the electric motor is connected to the pump, A pump device, wherein the transmission device, the electric motor, and the inverter are configured such that a cooling fluid can be circulated in common. 2. The pump device according to claim 1, wherein the inverter is in contact with the electric motor.